Method for propagating network management data for energy-efficient iot network management and energy-efficient iot node apparatus

ABSTRACT

A method for propagating network management data for energy-efficient internet of things network management and an energy-efficient internet of things node apparatus are disclosed herein. The method includes dividing a plurality of sub-nodes into at least two terminal sub-nodes and the remaining intermediate sub-nodes, and determining a transmission path so that the terminal sub-nodes and the intermediate sub-nodes satisfy an acyclic graph condition, dividing the plurality of pieces of data of network management information into at least two data groups, and transmitting one of the at least two data groups to one of the terminal sub-nodes respectively, transmitting the data of the received data group to adjacent intermediate sub-nodes, performing network coding on selected two pieces of data, transmitting the network-coded data to the at least two intermediate adjacent sub-nodes, and decoding the received network-coded data using previously held data.

BACKGROUND

1. Technical Field

The present invention relates generally to the Internet of Things (IoT) and, more particularly, to technology for the network management of the IoT.

2. Description of the Related Art

Research on IoT started from a concept of assigning information processing function, data transmission and reception functions to things and connecting the things to a public network, such as the Internet, and has explosively proliferated through fusion with other concepts, such as a mobile network, smart phones, ubiquitous network, sensor network, big data technology, etc.

Although a situation varies depending on the intrinsic function and shape of a thing, a device having a network function (hereinafter referred to as a “network function device”) may be supposedly a device that operates based on a battery in order to attach such a network function device to a thing which is mobile, portable, or non-grid, while maintaining the function and shape of the thing.

Since the capabilities of the IoT increase in proportion to the number of things it is connected with, the energy efficiency of network function devices attached to respective things is a matter of great concern.

In general, the energy efficiency of a network function device, i.e., a node, attached to a thing is dependent on the power consumption during transmission and reception operations, rather than the power consumption during information collection operations and command processing operations. Although the dissipated power of transmission and reception operations are determined by various factors, such as transmission distance, bit error rate (BER), transmission protocols, etc., a factor that greatly influences the energy over a long period of time is also the number of transmissions.

Since a sub-node, a node among IoT nodes consisting a sub-network, which functions as a gateway to an upper layer, must transmit data collected from other sub-nodes to the upper layer, and transmit network management information and commands received from the upper layer to other sub-nodes, the sub-node should perform transmission operations much more than other sub-nodes do. As a result, the energy of the battery of the specific sub-node functioning as a gateway will be consumed earlier, and therefore the sub-network will not function normally. This phenomenon is called as energy hole problem.

In particular, network management information, such as firmware update, security data, network configuration information, etc., which must be transmitted to all sub-nodes from upper layer may rapidly consume the battery of a specific sub-node that functions as a gateway.

Therefore, there is a need for a method for propagating network management information to sub-nodes that constitute the IoT in an energy-efficient manner.

SUMMARY

The present invention is directed to providing a method for propagating network management data for energy-efficient IoT network management and an energy-efficient IoT node device.

At least some embodiments of the present invention are directed to the provision of a method for propagating network management data for energy-efficient IoT network management and an energy-efficient IoT node device, which are capable of preventing a transmission operation from concentrating at a specific node device functioning as a gateway, thereby minimizing the energy hole problem in which the energy of a specific node device is exhausted early.

At least some embodiments of the present invention are directed to the provision of a method for propagating network management data for energy-efficient IoT network management and an energy-efficient IoT node device, which are capable of reducing the number of transmissions of which a specific node device functioning as a gateway takes charge in order to complete the propagation of network management information.

At least some embodiments of the present invention are directed to the provision of a method for propagating network management data for energy-efficient IoT network management and an energy-efficient IoT node device, which are capable of reducing the total number of transmissions occurring between node devices in order to complete the propagation of network management information.

At least some embodiments of the present invention are directed to the provision of a method for propagating network management data for energy-efficient IoT network management and an energy-efficient IoT node device, which are capable of reducing the total time it takes to complete the propagation of network management information.

In accordance with an aspect of the present invention, there is provided a method for propagating network management data for the energy-efficient management of an Internet of Things (IoT) network including a main node and a plurality of sub-nodes, the method including the steps of: (a) dividing, by the main node, the plurality of sub-nodes into at least two terminal sub-nodes and the remaining intermediate sub-nodes, and determining, by the main node, a transmission path so that the at least two terminal sub-nodes locate at end points, respectively, and the terminal sub-nodes and the intermediate sub-nodes satisfy an acyclic graph condition; (b) dividing, by the main node, the plurality of pieces of data of network management information into at least two data groups, and transmitting, by the main node, one of the at least two data groups to one of the terminal sub-nodes, respectively; (c) transmitting, by each of the terminal sub-nodes, the data of the received data group to adjacent intermediate sub-nodes on the transmission path on a per-unit basis; (d) performing, by each of the intermediate sub-nodes, network coding on two pieces of data selected for appropriateness for network coding transmission for at least two adjacent intermediate sub-nodes or for at least one adjacent intermediate sub-node and one of the terminal sub-nodes, and transmitting, by the intermediate sub-node, the network-coded data to the at least two intermediate adjacent sub-nodes or to the at least one adjacent intermediate sub-node and the terminal sub-node; and (e) decoding, by the intermediate sub-node, the received network-coded data using previously held data.

At step (a), the terminal sub-nodes may be two in number, and the acyclic graph condition may be a condition in which all sub-nodes are present on a single linear graph.

Step (d) may include the step of selecting, by the intermediate sub-node, among data which are held by the intermediate sub-node, data which are present only at any one of the at least two adjacent sub-nodes, as the at least two pieces of data appropriate for network coding transmission.

The at least two pieces of data appropriate for network coding transmission may be selected for two intermediate sub-nodes s_(n−1) and s_(n+1) adjacent to an intermediate sub-node s_(n) according to the following equation:

d _(i) ε{circumflex over (N)} _(n) ∩{circumflex over (N)} _(n+1)

d _(j) ε{circumflex over (N)} _(n) ∩{circumflex over (N)} _(n−1)

where d_(i) is data common to a to-be-transmitted data group {circumflex over (N)}_(n) of the intermediate sub-node s_(n) and a to-be-transmitted data group {circumflex over (N)}_(n+1) of the intermediate sub-node s_(n+1), and d_(j) is data common to the to-be-transmitted data group {circumflex over (N)}_(n) of the intermediate sub-node s_(n) and a to-be-transmitted data group {circumflex over (N)}_(n−1) of the intermediate sub-node s_(n−1); and

the to-be-transmitted data group {circumflex over (N)}_(n) may be defined by the following equations:

{circumflex over (N)} _(n) =N _(n) −Y _(n)

Y _(n)=(N _(n−1) ∩N _(n) ∩N _(n+1))

where N_(n−1), N_(n) and N_(n+1) are each a data group that includes pieces of data that are held by each of the intermediate sub-nodes s_(n−1), s_(n) and s_(n+1).

The at least two pieces of data appropriate for network coding transmission may be selected for two intermediate sub-nodes s_(n−1) and s_(n+1) adjacent to an intermediate sub-node s_(n) according to the following equation:

d _(i) ε{circumflex over (N)} _(n) ∩N _(n+1)

d _(j) ε{circumflex over (N)} _(n) ∩N _(n−1)

where d_(i) is data common to a to-be-transmitted data group {circumflex over (N)}_(n) of the intermediate sub-node s_(n) and a to-be-transmitted data group N_(n+1) of the intermediate sub-node s_(n+1), and d_(j) is data common to the to-be-transmitted data group {circumflex over (N)}_(n) of the intermediate sub-node s_(n) and a to-be-transmitted data group N_(n−1) of the intermediate sub-node s_(n−1); and

the to-be-transmitted data group {circumflex over (N)}_(n) may be defined by the following equations:

{circumflex over (N)} _(n) =N _(n) −Y _(n)

Y _(n)=(N _(n−1) ∩N _(n) ∩N _(n+1))

where N_(n−1), N_(n) and N_(n+1) are each a data group that includes pieces of data that are held by each of the intermediate sub-nodes s_(n−1), s_(n) and s_(n+1).

Step (d) may include the steps of:

performing, by the intermediate sub-node, network coding on the selected two pieces of data d_(i) and d_(j) according to the following equation:

{circumflex over (d)}=d _(i) ⊕d _(j); and

transmitting, by the intermediate sub-node, the network-coded data {circumflex over (d)} to at least two adjacent intermediate sub-nodes or to an adjacent intermediate sub-node and an adjacent terminal sub-node.

Step (e) may include the steps of:

obtaining, by the intermediate sub-node s_(n−1) having received the network-coded data {circumflex over (d)} from the intermediate sub-node s_(n), data d_(i) based data d_(j) being held according to the following equation:

d _(i) ={circumflex over (d)}⊕d _(j), where d _(j) εN _(n−1); and

obtaining, by the intermediate sub-node s_(n+1) having received the network-coded data {circumflex over (d)} from the intermediate sub-node s_(n), data d_(j) based on the data d_(i) being held according to the following equation:

d _(j) ={circumflex over (d)}⊕d _(i), where d _(i) εN _(n+1).

The method may further include the step of, if the two pieces of data appropriate for network coding transmission have not been selected at step (d), relaying, by the intermediate sub-node, data from its adjacent previous sub-node to its adjacent subsequent sub-node on the transmission path.

In accordance with another aspect of the present invention, there is provided a computer-readable non-transitory storage medium storing a program written to implement a method for propagating network management data according to an embodiment in a computer.

In accordance with still another aspect of the present invention, there is provided an energy-efficient Internet of Things (IoT) node device that functions as any one of a main node and a sub-node and that constitutes part of an energy-efficient IoT network, wherein: if the energy-efficient IoT node device functions as the main node, the energy-efficient IoT node device is operative to: divide the plurality of sub-nodes of the energy-efficient IoT network into at least two terminal sub-nodes and the remaining intermediate sub-nodes, and determine a transmission path so that the at least two terminal sub-nodes locate at end points, respectively, and the terminal sub-nodes and the intermediate sub-nodes satisfy an acyclic graph condition; and divide the plurality of pieces of data of network management information into at least two data groups, and transmit one of the at least two data groups to one of the terminal sub-nodes, respectively.

If the energy-efficient IoT node device functions as the sub-node, the energy-efficient IoT node device may be operative to: transmit the data of the data group, received from the main node, to adjacent intermediate sub-nodes on the transmission path on a per-unit basis; perform network coding on two pieces of data selected for appropriateness for network coding transmission for at least two adjacent intermediate sub-nodes or for at least one adjacent intermediate sub-node and one of the terminal sub-nodes, and transmit the network-coded data to the at least two intermediate adjacent sub-nodes or to the at least one adjacent intermediate sub-node and the terminal sub-node; and decode the received network-coded data using previously held data.

In accordance with still another aspect of the present invention, there is provided an energy-efficient Internet of Things (IoT) network system including a main node and a plurality of sub-nodes; wherein the main node divides the plurality of sub-nodes of the energy-efficient IoT network into at least two terminal sub-nodes and the remaining intermediate sub-nodes, determines a transmission path so that the at least two terminal sub-nodes locate at end points, respectively, and the terminal sub-nodes and the intermediate sub-nodes satisfy an acyclic graph condition, divides the plurality of pieces of data of network management information into at least two data groups, and transmits one of the at least two data groups to one of the terminal sub-nodes, respectively; and wherein each of the plurality of sub-nodes, if the sub-node is classified as a terminal sub-node, transmits the data of the data group, received from the main node, to adjacent intermediate sub-nodes on the transmission path on a per-unit basis, and, if the sub-node is classified as an intermediate sub-node, performs network coding on two pieces of data selected for appropriateness for network coding transmission for at least two adjacent intermediate sub-nodes or for at least one adjacent intermediate sub-node and one of the terminal sub-nodes, transmits the network-coded data to the at least two intermediate adjacent sub-nodes or to the at least one adjacent intermediate sub-node and the terminal sub-node, and decodes the received network-coded data using previously held data.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and other objects, features and advantages of the present invention will be more clearly understood from the following detailed description taken in conjunction with the accompanying drawings, in which:

FIG. 1 is a conceptual diagram showing the hierarchical network structure of an IoT network for a method for propagating network management data for energy-efficient IoT network management according to an embodiment of the present invention;

FIG. 2 is a flowchart illustrating a method for propagating network management data for energy-efficient IoT network management according to an embodiment of the present invention;

FIG. 3 is a diagram illustrating the data transmission operation of sub-nodes based on network coding in a method for propagating network management data for energy-efficient IoT network management according to an embodiment of the present invention; and

FIG. 4 is a graph showing the comparison between the number of transmissions based on a method for propagating network management data for energy-efficient IoT network management according to an embodiment of the present invention and the number of transmissions based on a common transmission method.

DETAILED DESCRIPTION

This work was supported by the National Research Foundation of KOREA (NRF) and Center for Women In Science, Engineering and Technology (WISET).

With regard to embodiments of the present invention disclosed herein, specific structural and functional descriptions are given merely for the purpose of illustrating the embodiments of the present invention.

Embodiments of the present invention may be practiced in various forms, and the present invention should not be construed as being limited to embodiments disclosed herein.

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings. The same reference numerals will be used to denote the same components throughout the accompanying drawings, and redundant descriptions of the same components will be omitted.

Throughout the specification, IoT node devices and main node devices may be referred to as sub-nodes and a main node unless they are used in a clearly different technical context.

FIG. 1 is a conceptual diagram showing the hierarchical network structure of an IoT network for a method for propagating network management data for energy-efficient IoT network management according to an embodiment of the present invention.

Referring to FIG. 1, the hierarchical network structure 10 of the IoT is hierarchically configured to include an upper layer network 110 and at least one lower layer network 120.

The upper layer network 110 is a network connected to the external Internet or an external IoT platform server via a backbone. The upper layer network 110 may include a central hub 111 connected to the outside via the backbone, and main node devices 112 (or a main node), selected (voted) from IoT sub-node devices 121, 122, 123 and 124 (or sub-nodes) to function as a gateway, or previously set as a main device.

The lower layer network 120 may include the IoT node devices 121, 122, 123 and 124 attached to things, respectively, and configured to collect information about the things and exchange data with the upper layer network 110.

In an embodiment, the main node 112 of the upper layer network 110 has the substantially identical hardware and principal functions as the sub-nodes 121, 122, 123 and 124, but may be selected to function as a gateway between the upper layer network 110 and the lower layer network 120 or may be manually designated.

In another embodiment, the main node 112 of the upper layer network 110 may be based on powerful hardware than the sub-nodes 121, 122, 123 and 124 to further function as a gateway, or may be specialized for gateway functionality.

The central hub 111, the main node 112 and the sub-nodes 121, 122, 123 and 124 may constitute an IoT network system.

Meanwhile, it is preferred that in a method for propagating network management data for energy-efficient IoT network management according to the present invention, the sub-nodes 121, 122, 123 and 124 of the lower layer network 120 can form a transmission path, satisfying an acyclic graph condition in which there exist no internal cycle, at least during the propagation of network management information. For example, the sub-nodes 121, 122, 123 and 124 may form a transmission path that can be arranged as a string. However, this condition is not required for transmission and reception of information other than the network management information of the present invention.

The main node 112 may divide the data of the network management information into a plurality of data groups, for example, two data groups, and may transmit one of the plurality of data groups, for example, one of the two data groups, to one of a plurality of sub-nodes, for example, one of two sub-nodes 121 and 124, respectively, corresponding to the end points of the transmission path formed by the sub-nodes 121, 122, 123 and 124 of the lower layer network 120. Thereafter, the sub-nodes 121 and 124 corresponding to the end points transmit the data of their received data groups to the sub-nodes 122 and 123 adjacent over the transmission path, using a network coding technique. In the same manner, the sub-nodes 122 or 123 also transmit their received data to other sub-nodes adjacent over the transmission path using the network coding technique.

Referring to FIGS. 2 and 3 in order to describe the method for propagating network management data for energy-efficient IoT network management according to the present invention in greater detail, FIG. 2 is a flowchart illustrating a method for propagating network management data for energy-efficient IoT network management according to an embodiment of the present invention, and FIG. 3 is a diagram illustrating the data transmission operation of sub-nodes based on network coding in a method for propagating network management data for energy-efficient IoT network management according to an embodiment of the present invention.

The method for propagating network management data for energy-efficient IoT network management according to the embodiment of the present invention illustrated in FIG. 2 is performed on a transmission path, such as that illustrated in FIG. 3.

As illustrated in FIG. 3, N sub-nodes s₁, s₂, . . . , s_(n−1), s_(n), s_(n+1), . . . , s_(N−1), s_(N) may form a transmission path that satisfies an acyclic graph condition without internal cycle, for example, a transmission path that is arranged as a string, in order to propagate at least network management information.

Although each of the sub-nodes s₁ and s_(N) present at two end points of the transmission path is connected to a single adjacent sub-node s₂ or s_(N−1), respectively, n-th sub-nodes s_(n), other than the sub-nodes s₁ and s_(N) at end points, transmit and receive data to and from two adjacent sub-nodes s_(n−1) and s_(n+1) using a network coding technique.

In this context, a method for propagating network management data for energy-efficient IoT network management according to an embodiment of the present invention may start from step S21.

At step S21, the main node 112 may classify the N sub-nodes s₁, s₂, . . . , s_(n−1), s_(n), s_(n+1), . . . , s_(N−1), s_(N) into at least two terminal sub-nodes s₁ and s_(N) and the remaining intermediate sub-nodes s₂, . . . , s_(n−1), s_(n), s_(n+1), . . . , and s_(N−1), and determines a transmission path such that the at least two terminal sub-nodes s₁ and s_(N) place at respective end points of the transmission path and all of the terminal sub-nodes s₁ and s_(N) and the intermediate sub-nodes s₂, . . . , s_(n−1), s_(n), s_(n+1), . . . , and s_(N−1) satisfy an acyclic graph condition.

In this case, the main node 112 may be one of the sub-nodes and be selected as a gateway from the sub-nodes, or may be a node specialized for a main node different from the sub-nodes.

At step S22, the main node 112 divides a plurality of pieces of data, constituting network management information, into at least two data groups, and transmits each of the plurality of data groups N₁ and N_(N) to each of the terminal sub-nodes s₁ and s_(N) present at a plurality of end points on the transmission path.

More specifically, the main node 112 divides L pieces of data d₁, d₂, . . . , d_(L), constituting network management information, received from the central hub 111 into two data groups N₁={d₁, . . . , d_(┌L/2┐)} and N_(N)={d_(┌L/2┐+1), . . . , d_(L)}, and transmits the data groups N₁ and N_(N) to the terminal sub-nodes s₁ and s_(N), respectively.

At step S23, each of the terminal sub-nodes s₁ and s_(N) at a plurality of end points on the transmission path receives one of the plurality of data groups N₁ and N_(N) from the main node 112.

At step S24, the terminal sub-node s₁ or s_(N) transmits data of the received data group N₁ or N_(N) piece by piece to an adjacent intermediate sub-node s₂, . . . , s_(n−1), s_(n), s_(n+1), . . . , or s_(N−1) on the transmission path.

At step S25, an intermediate sub-node s₂, . . . , s_(n−1), s_(n), s_(n+1), . . . , or s_(N−1) selects two pieces of data d_(i) and d_(j) appropriate for network coding transmission to at least two adjacent sub-nodes of the intermediate sub-nodes s₂, . . . , s_(n−1), s_(n), s_(n+1), . . . , and s_(N−1) or to at least one intermediate sub-node s₃ or s_(N−2) and the terminal sub-node s₁ or s_(N).

If the two pieces of data d_(i) and d_(j) have been selected, the process proceeds to step S26. If there is no appropriate data, the process proceeds to step S28 of performing transmission without network coding. For example, in the early stage of the propagation of network management data, each of the intermediate sub-nodes may have only a few pieces of data, not enough for network coding. In this case, a sub-node on the transmission path may relay data to another adjacent sub-node without network coding using a common method.

More specifically, at step S25, each of the intermediate sub-nodes s₂, . . . , s_(n−1), s_(n), s_(n+1), . . . , and s_(N−1) may select the two pieces of data d_(i) and d_(j), appropriate for network coding transmission, among data received by the corresponding intermediate sub-node, such that each piece of data d_(i) and d_(j) is present only at any one of at least two adjacent sub-nodes, not both of the adjacent sub-nodes.

Referring additionally to FIG. 3, an intermediate sub-node s_(n) neighbors two intermediate sub-nodes s_(n−1) and s_(n+1) on the transmission path, and the sub-nodes s⁻¹, s_(n) and s_(n+1) currently hold data groups N_(n−1), N_(n) and N_(n+1).

In this case, as shown in the following Equation 1, the three sub-nodes s_(n−1), s_(n) and s_(n+1) do not need to transmit the data group Y_(n) of data common to the data groups N_(n−1), N_(n) and N_(n+1):

Y _(n)=(N _(n−1) ∩N _(n) ∩N _(n+1))  (1)

Accordingly, data, which is appropriate for the network coding by the intermediate sub-node s_(n) to transmit to adjacent sub-nodes s_(n−1) and s_(n+1), is data from the data group N_(n) of the data held by the intermediate sub-node s_(n), exclusive of the data group Y_(n).

In this case, it should be noted that to determine the data group Y_(n) that the intermediate sub-node s_(n) does not need to transmit, the adjacent intermediate sub-nodes s_(n−1), s_(n) and s_(n+1) do not need to notify one another beforehand the data held by themselves.

Data d_(j) and d_(k) belonging to the data group N₁ are sequentially transmitted from the terminal sub-node s₁ to the right, and data d_(i) belonging to the data group N_(n) is sequentially transmitted from the terminal sub-node s_(N) to the left. Assume that an intermediate sub-node s_(n) holds data d_(i), d_(j) and d_(k) at a specific time. The intermediate sub-nod s_(n) has not yet transmitted the data d_(i), which is received from the intermediate sub-node s_(n+1), to the intermediate sub-node s_(n−1) yet, and has not yet transmitted the data d_(j), which is received from the intermediate sub-node s_(n−1), to the intermediate sub-node s_(n+1) yet. If the intermediate sub-node s_(n) has transmitted the data d_(k), which is received from the intermediate sub-node s_(n−1), to the intermediate sub-node s_(n+1) already, it may be logically determined that the data held in common by the three intermediate sub-nodes s_(n−1), s_(n) and s_(n+1) is only data d_(k).

Accordingly, a to-be-transmitted data group {circumflex over (N)}_(n) may be constructed, as shown in the following Equation 2:

{circumflex over (N)}=N _(n) −Y _(n)  (2)

The intermediate sub-node s_(n) may select at least two pieces of data, which are data present at the intermediate sub-node s_(n), and which are only present at any one of at least two adjacent sub-nodes s_(n−1) and s_(n+1) and are not present at the other sub-node s_(n+1) or s_(n−1), from the data of the to-be-transmitted data group {circumflex over (N)}_(n), as data d_(i) and d_(j) appropriate for network coding transmission.

More specifically, the intermediate sub-node s_(n) may select the two pieces of data d_(i) and d_(j) appropriate for network coding transmission according to Equation 3:

d _(i) ε{circumflex over (N)} _(n) ∩{circumflex over (N)} _(n+1)

d _(j) ε{circumflex over (N)} _(n) ∩{circumflex over (N)} _(n−1)  (3)

According to Equation 3, selected are the data d_(i) common to the to-be-transmitted data group {circumflex over (N)}_(n) of the n-th intermediate sub-node s_(n) and the to-be-transmitted data group {circumflex over (N)}_(n+1) of the (n+1)-th intermediate sub-node s_(n+1), and the data d_(j) common to the to-be-transmitted data group {circumflex over (N)}_(n) of the n-th intermediate sub-node s_(n) and the to-be-transmitted data group {circumflex over (N)}_(n−1) of the (n−1)-th intermediate sub-node s_(n−1). The data d_(i) is not present at the (n−1)-th intermediate sub-node s_(n−1) but is present both at the n-th intermediate sub-node s_(n) and the (n+1)-th intermediate sub-node s_(n+1). In contrast, the data d_(j) is not present at the (n+1)-th intermediate sub-node s_(n+1), but is present both at the n-th intermediate sub-node s_(n) and the (n−1)-th intermediate sub-node s_(n−1).

As for such an embodiment in which the intermediate sub-node s_(n) takes into account not only its own not-requiring-transmission data group Y_(n) but also the not-requiring-transmission data groups Y_(n+1) and Y_(n−1) of the adjacent intermediate sub-nodes s_(n+1) and s_(n−1), the n-th intermediate sub-node s_(n) must further take into account the to-be-transmitted data group {circumflex over (N)}_(n+1) and the to-be-transmitted data group {circumflex over (N)}_(n−1) of the respective adjacent sub-nodes s_(n+1) and s_(n−1) in order to select the two pieces of data d_(i) and d_(j) appropriate for network coding transmission according to Equation 3.

For example, since, in order to take into account the to-be-transmitted data group {circumflex over (N)}_(n+1) of the intermediate sub-node s_(n+1), the intermediate sub-node s_(n) must take into account the data groups N₁ and N_(n+1) of the intermediate sub-nodes s_(n) and s_(n+2) adjacent to the intermediate sub-node s_(n+1) according to Equations 1 and 2, an additional computational or transmission load may be required.

In contrast, in another embodiment, the intermediate sub-node s_(n) may take into account only its own not-requiring-transmission data group Y_(n).

More specifically, the intermediate sub-node s_(n) may select the two pieces of data d_(i) and d_(j) appropriate for network coding transmission according to Equation 4:

d _(i) ε{circumflex over (N)} _(n) ∩N _(n+1)

d _(j) ε{circumflex over (N)} _(n) ∩N _(n−1)  (4)

According to Equation 4, selected are the data d_(i) common to the to-be-transmitted data group {circumflex over (N)}_(n) of the n-th intermediate sub-node s_(n) and the to-be-transmitted data group N_(n+1) of the (n+1)-th intermediate sub-node s_(n+1), and the data d_(j) common to the to-be-transmitted data group {circumflex over (N)}_(n) of the n-th intermediate sub-node s_(n) and the to-be-transmitted data group N_(n−1) of the (n−1)-th intermediate sub-node s_(n−1). The data d_(i) is not present at the (n−1)-th intermediate sub-node s_(n−1) but is present both at the n-th intermediate sub-node s_(n) and the (n+1)-th intermediate sub-node s_(n+1). In contrast, the data d_(j) is not present at the (n+1)-th intermediate sub-node s_(n+1), but is present both at the n-th intermediate sub-node s_(n) and the (n−1)-th intermediate sub-node s_(n−1).

In this embodiment, the intermediate sub-node s_(n) takes into account only its own not-requiring-transmission data group Y_(n), but does not take into account the not-requiring-transmission data groups Y_(n+1) and Y_(n−1) of the adjacent intermediate sub-nodes s_(n+1) and s_(n−1).

At step S26, the intermediate sub-nodes s₂, . . . , s_(n−1), s_(n), s_(n+1), . . . , and s_(N−1) perform network coding on the selected two pieces of data d_(i) and d_(j), and transmits the network-coded data to at least two adjacent intermediate sub-nodes s₂, . . . , s_(n−1), s_(n), s_(n+1), . . . , and s_(N−1) or to the adjacent intermediate sub-node s₃ or s_(N−2) and the adjacent terminal sub-node s₁ or s_(N).

More specifically, the intermediate sub-nodes s₂, . . . , s_(n−1), s_(n), s_(n+1), . . . , and s_(N−1) perform network coding on the selected two pieces of data d_(i) and d_(j) according to Equation 5:

{circumflex over (d)}=d _(i) ⊕d _(j)  (5)

The network-coded data {circumflex over (d)} is transmitted from the intermediate sub-node s_(N) to the two adjacent intermediate sub-nodes s_(n+1) and s_(n−1).

In this case, the operator “⊕” refers to an addition operation defined in the Galois Field (GF).

At step S27, the intermediate sub-node s₂, . . . , s_(n−1), s_(n), s_(n+1), . . . , or s_(N−1) receives the network-coded data {circumflex over (d)}, and decodes the received network-coded data {circumflex over (d)} using previously held data d_(i) or d_(j).

In the example of FIG. 3, the (n−1)-th intermediate sub-node s_(n−1) receives the network-coded data {circumflex over (d)} from the intermediate sub-node s_(n) then and obtains data d_(i) based on the data d_(j) being held, as shown in Equation 6:

d _(i) ={circumflex over (d)}⊕d _(j) , where d _(j) εN _(n−1)  (6)

The decoded data d_(i) becomes a new element of the data group N_(n−1) obtained by the (n−1)-th intermediate sub-node s_(n−1).

In the same manner, the (n+1)-th intermediate sub-node s_(n+1) receives the network-coded data {circumflex over (d)} from the intermediate sub-node s_(n) and obtains data d_(j) based on the data d_(i) being held, as shown in Equation 7:

d _(j) ={circumflex over (d)}⊕d _(i), where d _(i) εN _(n+1)  (7)

The decoded data d_(j) becomes a new element of the data group N_(n+1) obtained by the (n+1)-th intermediate sub-node s_(n+1).

If the data d_(i) and d_(j) appropriate for network coding transmission have not been selected at step S25, the intermediate sub-node s₂, . . . , s_(n−1), s_(n), s_(n+1), . . . , or s_(N−1) may relay data from its adjacent antecedent sub-node to its adjacent subsequent sub-node on the transmission path at step S28.

FIG. 4 is a graph showing the comparison between the number of transmissions based on a method for propagating network management data for energy-efficient IoT network management according to an embodiment of the present invention and the number of transmissions based on a common transmission method.

Referring to FIG. 4, when the number of sub-nodes is N and the size of network management data (for example, the number of packets) is L, the number of transmissions required when individual sub-nodes, along a transmission path satisfying an acyclic graph condition, simply perform relay (indicated by “no coding”) is compared with the number of transmissions required when individual sub-nodes perform transmission using network coding via a transmission path by means of a method for propagating network management data for energy-efficient IoT network management according to the present invention (indicated by “network coding”).

When the number of packets increases (L=3), the difference in the number of transmissions between two methods is not significant.

When the number of packets further increases (L=10), the number of transmissions in the method for propagating network management data using network coding according to the present invention is reduced by about 10 to 15% points compared to the simple relay method.

When the number of packets further increases (L=20), the number of transmissions in the method for propagating network management data using network coding according to the present invention is reduced by about 20 to 30% points compared to the simple relay method.

When the firmware of a sensor node device constituting part of a sensor network or security data has a size of a few MB, the number of packets may range from a few hundreds to a few thousands if it is assumed that the size of each packet is 8 kb. Accordingly, it may be expected that the method for propagating network management data using network coding according to the present invention can significantly reduce the number of transmissions compared to the simple relay method.

A method for propagating network management data for energy-efficient IoT network management and an energy-efficient IoT node device according to at least some embodiments of the present invention are capable of preventing transmission operations from concentrating at a specific node device functioning as a gateway, thereby minimizing chance of energy hole problem in which the energy of a specific node device is to be exhausted earlier.

A method for propagating network management data for energy-efficient IoT network management and an energy-efficient IoT node device according to at least some embodiments of the present invention are capable of reducing the number of transmissions that a specific node device functioning as a gateway carries out in order to complete the propagation of network management information.

A method for propagating network management data for energy-efficient IoT network management and an energy-efficient IoT node device according to at least some embodiments of the present invention are capable of reducing the total number of transmissions occurring between nodes in order to complete the propagation of network management information.

A method for propagating network management data for energy-efficient IoT network management and an energy-efficient IoT node device according to at least some embodiments of the present invention are capable of reducing the total time to complete the propagation of network management information.

The above embodiments and the accompanying drawings are intended merely to clearly illustrate part of the technical spirit of the present invention, and it will be apparent to those skilled in the art that modifications and specific embodiments that those skilled in the art can easily derive from the present specification and the accompanying drawings are all included in the range of the rights of the present invention.

Furthermore, the apparatus according to at least one embodiment of the present invention may be implemented as a computer-readable code on a computer-readable storage medium. The computer-readable storage medium includes all types of storage devices on which data that can be read by a computer system is stored. Examples of the computer-readable storage medium include read-only memory (ROM), random access memory (RAM), an optical disk, a magnetic tape, a floppy disk, nonvolatile memory, etc. Furthermore, the computer-readable storage medium may be distributed across computer systems connected to each other over a network, and computer-read able code may be stored and executed in the computer systems in a distributed manner. 

1. A method for propagating network management data for energy-efficient management of an Internet of Things (IoT) network including a main node and a plurality of sub-nodes, the method comprising the steps of: (a) dividing, by the main node, the plurality of sub-nodes into at least two terminal sub-nodes and remaining intermediate sub-nodes, and determining, by the main node, a transmission path so that the at least two terminal sub-nodes locate at end points, respectively, and the terminal sub-nodes and the intermediate sub-nodes satisfy an acyclic graph condition; (b) dividing, by the main node, a plurality of pieces of data of network management information into at least two data groups, and transmitting, by the main node, one of the at least two data groups to one of the terminal sub-nodes, respectively; (c) transmitting, by each of the terminal sub-nodes, data of the received data group to adjacent intermediate sub-nodes on the transmission path on a per-unit basis; (d) performing, by each of the intermediate sub-nodes, network coding on two pieces of data selected for appropriateness for network coding transmission for at least two adjacent intermediate sub-nodes or for at least one adjacent intermediate sub-node and one of the terminal sub-nodes, and transmitting, by the intermediate sub-node, the network-coded data to the at least two intermediate adjacent sub-nodes or to the at least one adjacent intermediate sub-node and the terminal sub-node; and (e) decoding, by the intermediate sub-node, the received network-coded data using previously held data.
 2. The method of claim 1, wherein at step (a), number of the terminal sub-nodes is two, and the acyclic graph condition is a condition in which all sub-nodes are present on a single linear graph.
 3. The method of claim 1, wherein step (d) comprises the step of selecting, by the intermediate sub-node, among data which are held by the intermediate sub-node, data which are present only at any one of the at least two adjacent sub-nodes, as the at least two pieces of data appropriate for network coding transmission.
 4. The method of claim 3, wherein: the at least two pieces of data appropriate for network coding transmission are selected for two intermediate sub-nodes s_(n−1) and s_(n+1) adjacent to an intermediate sub-node s_(n) according to the following equation: d _(i) ε{circumflex over (N)} _(n) ∩{circumflex over (N)} _(n+1) d _(j) ε{circumflex over (N)} _(n) ∩{circumflex over (N)} _(n−1) where d_(i) is data common to a to-be-transmitted data group {circumflex over (N)}_(n) of the intermediate sub-node s_(n) and a to-be-transmitted data group {circumflex over (N)}_(n+1) of the intermediate sub-node s_(n+1), and d_(j) is data common to the to-be-transmitted data group {circumflex over (N)}_(n) of the intermediate sub-node s_(n) and a to-be-transmitted data group {circumflex over (N)}_(n−1) of the intermediate sub-node s_(n−1); and the to-be-transmitted data group {circumflex over (N)}_(n) is defined by the following equations: {circumflex over (N)} _(n) =N _(n) −Y _(n) Y _(n)=(N _(n−1) ∩N _(n) ∩N _(n+1)) where N_(n−1), N_(n) and N_(n+1) are respectively a data group that includes pieces of data that are held by each of the intermediate sub-nodes s_(n−1), s_(n) and s_(n+1).
 5. The method of claim 3, wherein: the at least two pieces of data appropriate for network coding transmission are selected for two intermediate sub-nodes s_(n−1) and s_(n+1) adjacent to an intermediate sub-node s_(n) according to the following equation: d _(i) ε{circumflex over (N)} _(n) ∩N _(n+1) d _(j) ε{circumflex over (N)} _(n) ∩N _(n−1) where d_(i) is data common to a to-be-transmitted data group {circumflex over (N)}_(n) of the intermediate sub-node s_(n) and a to-be-transmitted data group N_(n+1) of the intermediate sub-node s_(n+1), and d_(j) is data common to the to-be-transmitted data group {circumflex over (N)}_(n), of the intermediate sub-node s_(n) and a to-be-transmitted data group N_(n−1) of the intermediate sub-node s_(n−1); and the to-be-transmitted data group {circumflex over (N)}_(n) is defined by the following equations: {circumflex over (N)} _(n) =N _(n) −Y _(n) Y _(n)=(N _(n−1) ∩N _(n) ∩N _(n+1)) where N_(n−1), N_(n) and N_(n+1) are respectively a data group that includes pieces of data that are held by each of the intermediate sub-nodes s_(n−1), s_(n) and s_(n+1).
 6. The method of claim 5, wherein step (d) comprises the steps of: performing, by the intermediate sub-node, network coding on the selected two pieces of data d_(i) and d_(j) according to the following equation: {circumflex over (d)}=d _(i) ⊕d _(j); and transmitting, by the intermediate sub-node, the network-coded data {circumflex over (d)} to at least two adjacent intermediate sub-nodes or to an adjacent intermediate sub-node and an adjacent terminal sub-node.
 7. The method of claim 6, wherein step (e) comprises the steps of: obtaining, by the (n−1)th intermediate sub-node s_(n−1), having received the network-coded data {circumflex over (d)} from the intermediate sub-node s_(n), data d_(i) based on the data d_(j) being held according to the following equation: d _(i) ={circumflex over (d)}⊕d _(j), where d _(j) εN _(n−1); and obtaining, by the (n+1)th intermediate sub-node s_(n+1), having received the network-coded data {circumflex over (d)} from the intermediate sub-node s_(n), data d_(j) based on the data d_(i) being held according to the following equation: d _(j) ={circumflex over (d)}⊕d _(i), where d _(i) εN _(n+1).
 8. The method of claim 1, further comprising the step of, if the two pieces of data appropriate for network coding transmission have not been selected at step (d), relaying, by the intermediate sub-node, data from its adjacent previous sub-node to its adjacent subsequent sub-node on the transmission path.
 9. A computer-readable non-transitory storage medium storing a program written to implement the method for propagating network management data set forth in claim
 1. 10. An energy-efficient Internet of Things (IoT) node device that functions as any one of a main node or a sub-node and that constitutes part of an energy-efficient IoT network, wherein: if the energy-efficient IoT node device functions as the main node, the energy-efficient IoT node device is operative to: divide a plurality of sub-nodes of the energy-efficient IoT network into at least two terminal sub-nodes and remaining intermediate sub-nodes, and determine a transmission path so that the at least two terminal sub-nodes locate at end points, respectively, and the terminal sub-nodes and the intermediate sub-nodes satisfy an acyclic graph condition; and divide a plurality of pieces of data of network management information into at least two data groups, and transmit the at least two data groups to the terminal sub-nodes, respectively.
 11. The energy-efficient IoT node device of claim 10, wherein: if the energy-efficient IoT node device functions as the sub-node, the energy-efficient IoT node device is operative to: transmit data of the data group, received from the main node, to adjacent intermediate sub-nodes on the transmission path on a per-unit basis; perform network coding on two pieces of data selected for appropriateness for network coding transmission with respect to at least two adjacent intermediate sub-nodes or to at least one adjacent intermediate sub-node and one of the terminal sub-nodes, and transmit the network-coded data to the at least two intermediate adjacent sub-nodes or to the at least one adjacent intermediate sub-node and the terminal sub-node; and decode the received network-coded data using previously held data.
 12. The energy-efficient IoT node device of claim 10, wherein the terminal sub-nodes are two in number, and the acyclic graph condition is a condition in which all sub-nodes are present on a single linear graph.
 13. The energy-efficient IoT node device of claim 10, wherein the intermediate sub-node is operative to select data, among data which are held by the intermediate sub-node, data which are present only at any one of the at least two adjacent sub-nodes, as the at least two pieces of data appropriate for network coding transmission.
 14. The energy-efficient IoT node device of claim 13, wherein the at least two pieces of data appropriate for network coding transmission are selected for two intermediate sub-nodes s_(n−1) and s_(n+1) adjacent to an intermediate sub-node s_(n) according to the following equation: d _(i) ε{circumflex over (N)} _(n) ∩{circumflex over (N)} _(n+1) d _(j) ε{circumflex over (N)} _(n) ∩{circumflex over (N)} _(n−1) where d_(i) is data common to a to-be-transmitted data group {circumflex over (N)}_(n) of the intermediate sub-node s_(n) and a to-be-transmitted data group {circumflex over (N)}_(n+1) of the intermediate sub-node s_(n+1), and d_(j) is data common to the to-be-transmitted data group {circumflex over (N)}_(n) of the intermediate sub-node s_(n) and a to-be-transmitted data group {circumflex over (N)}_(n−1) of the intermediate sub-node s_(n−1); and the to-be-transmitted data group {circumflex over (N)}_(n) is defined by the following equations: {circumflex over (N)} _(n) =N _(n) −Y _(n) Y _(n)=(N _(n−1) ∩N _(n) ∩N _(n+1)) where N_(n−1), N_(n) and N_(n+1) are each a data group that includes pieces of data that are held by each of the intermediate sub-nodes s_(n−1), s_(n) and s_(n+1), respectively.
 15. The energy-efficient IoT node device of claim 13, wherein: the at least two pieces of data appropriate for network coding transmission are selected for two intermediate sub-nodes s_(n−1) and s_(n+1) adjacent to an intermediate sub-node s_(n) according to the following equation: d _(i) ε{circumflex over (N)} _(n) ∩N _(n+1) d _(j) ε{circumflex over (N)} _(n) ∩N _(n−1) where d_(i) is data common to a to-be-transmitted data group {circumflex over (N)}_(n) of the intermediate sub-node s_(n) and a to-be-transmitted data group N_(n+1) of the intermediate sub-node s_(n+1), and d_(j) is data common to the to-be-transmitted data group {circumflex over (N)}_(n) of the intermediate sub-node s_(n) and a to-be-transmitted data group N_(n−1) of the intermediate sub-node s_(n−1); and the to-be-transmitted data group {circumflex over (N)}_(n) is defined by the following equations: {circumflex over (N)} _(n) =N _(n) −Y _(n) Y _(n)=(N _(n−1) ∩N _(n) ∩N _(n+1)) where N_(n−1), N_(n) and N_(n+1) are respectively a data group that includes pieces of data that are held by each of the intermediate sub-nodes s_(n−1), s_(n) and s_(n+1).
 16. The energy-efficient IoT node device of claim 15, wherein the intermediate sub-node is operative to: perform network coding on the selected two pieces of data d_(i) and d_(j) according to the following equation: {circumflex over (d)}=d _(i) ⊕d _(j); and transmit the network-coded data {circumflex over (d)} to at least two adjacent intermediate sub-nodes or an adjacent intermediate sub-node and an adjacent terminal sub-node.
 17. The energy-efficient IoT node device of claim 16, wherein: the (n−1)th intermediate sub-node s_(n−1) having received the network-coded data {circumflex over (d)} from the intermediate sub-node s_(n) is operative to obtain data d_(i) based data d_(j) being held according to the following equation: d _(i) ={circumflex over (d)}⊕d _(j), where d _(j) εN _(n−1); and the (n+1)th intermediate sub-node s_(n+1), having received the network-coded data {circumflex over (d)} from the intermediate sub-node s_(n), obtains data d_(j) based on the data d_(i) being held according to the following equation: d _(j) ={circumflex over (d)}⊕d _(i), where d _(i) εN _(n−1).
 18. The energy-efficient IoT node device of claim 10, wherein if the two pieces of data appropriate for network coding transmission have not been selected, the energy-efficient IoT node device that functions as the sub-node is operative to relay data from its adjacent previous sub-node to its adjacent subsequent sub-node on the transmission path.
 19. An energy-efficient Internet of Things (IoT) network system comprising a main node and a plurality of sub-nodes; wherein the main node divides a plurality of sub-nodes of the energy-efficient IoT network into at least two terminal sub-nodes and remaining intermediate sub-nodes, determines a transmission path so that the at least two terminal sub-nodes locate at end points, respectively, and the terminal sub-nodes and the intermediate sub-nodes satisfy an acyclic graph condition, divides a plurality of pieces of data of network management information into at least two data groups, and transmits one of the at least two data groups to one of the terminal sub-nodes, respectively; and wherein each of the plurality of sub-nodes, if the sub-node is classified as a terminal sub-node, transmits data of the data group, received from the main node, to adjacent intermediate sub-nodes on the transmission path on a per-unit basis, and, if the sub-node is classified as an intermediate sub-node, performs network coding on two pieces of data selected for appropriateness for network coding transmission with respect to at least two adjacent intermediate sub-nodes or to at least one adjacent intermediate sub-node and one of the terminal sub-nodes, transmits the network-coded data to the at least two intermediate adjacent sub-nodes or to the at least one adjacent intermediate sub-node and the terminal sub-node, and decodes the received network-coded data using previously held data. 